Back to EveryPatent.com
United States Patent |
5,668,712
|
Cassese
,   et al.
|
September 16, 1997
|
Circuit for controlling a DCC converter in a power supply circuit for a
discharge lamp of a motor vehicle headlight
Abstract
A circuit for controlling a DC/AC converter of a power supply circuit for a
motor vehicle headlight discharge lamp, the circuit comprising a primary
circuit, voltage-feed means for feeding the primary circuit with voltage,
and a secondary circuit coupled to the primary circuit by mutual
induction, the secondary circuit delivering a voltage controlling the
non-conductive and conductive state of a MOSFET type transistor of the
DC/AC converter, the voltage that the power supply means deliver to the
primary circuit constituting a modulated high frequency carrier voltage,
the secondary circuit including means for converting the high frequency
voltage delivered to the primary circuit into a control voltage for the
transistor that is greater than or less than a given non-conductive or
conductive threshold, as a function of the modulation of said high
frequency voltage, the conversion means of the secondary circuit including
a switch connected between the grid and the source of the transistor, said
switch being open circuit while a high frequency voltage is being
delivered to the primary circuit and short circuiting the grid and the
source of said transistor when the said high frequency voltage disappears,
said conversion means also including first capacitor means providing the
control voltage to the switch, and second capacitor means which charge
whenever the high frequency is being delivered to the primary circuit and
which discharge into said first capacitor means when said high frequency
voltage disappears, whereby said first capacitor means then keep said
switch in the conductive condition.
Inventors:
|
Cassese; Bruno (Creteil, FR);
Wacheux; Patrick (Villejuif, FR);
Paul; Gilles (Fontenay-Aux-Roses, FR);
Herzberger; Eric (Gagny, FR);
Nicolai; Jean-Marc (Courbevoie, FR)
|
Assignee:
|
Valeo Electronique (Creteil, FR)
|
Appl. No.:
|
626183 |
Filed:
|
March 29, 1996 |
Foreign Application Priority Data
Current U.S. Class: |
363/95 |
Intern'l Class: |
H03K 017/687 |
Field of Search: |
363/22-26,50,55-56,97,131,133-134
307/10.1,9.1
|
References Cited
Foreign Patent Documents |
0 154 062 | Sep., 1985 | EP.
| |
0 477 587 A1 | Apr., 1992 | EP.
| |
2 701 339 | Aug., 1994 | FR.
| |
WO90/13178 | Nov., 1990 | WO.
| |
Primary Examiner: Krishnan; Aditya
Attorney, Agent or Firm: McCormick, Paulding & Huber
Claims
We claim:
1. A circuit for controlling a DC/AC converter of a power supply circuit
for a motor vehicle headlight discharge lamp, the circuit comprising a
primary circuit, voltage-feed means for feeding the primary circuit with
voltage, and a secondary circuit coupled to the primary circuit by mutual
induction, the secondary circuit delivering a voltage controlling the
non-conductive and conductive state of a MOSFET type transistor of the
DC/AC converter, the voltage that the power supply means deliver to the
primary circuit constituting a modulated high frequency carrier voltage,
the secondary circuit including means for converting the high frequency
voltage delivered to the primary circuit into a control voltage for the
transistor that is greater than or less than a given non-conductive or
conductive threshold, as a function of the modulation of said high
frequency voltage, the conversion means of the, secondary circuit
including a switch connected between the grid and the source of the
transistor, said switch being controlled by the voltage of the first
capacitor means, the conversion means comprising means which charge said
first capacitor means, when the high frequency voltage is delivered to the
primary circuit, so that the voltage of said capacitor means maintains the
switch in open circuit, wherein said conversion means also charge a second
capacitor means when the high frequency voltage is delivered to the
primary circuit, said second capacitor means discharging in the first
capacitor means when the high frequency voltage disappears, the voltage of
the first capacitor means thus charged by the second capacitor means being
of such a value that it keeps said switch in the conductive condition.
2. A circuit according to claim 1 wherein the switch is a MOS type
transistor, the first capacitor means are connected between the grid and
the source of said MOS type transistor, the second capacitor means being
connected at one end to said source and at the other end to resistive
means which remote end is connected to the grid of said MOS transistor,
the common end of said second capacitor means and said resistive means
being connected to the cathode of a diode which anode is connected to one
end of the secondary winding, the common point of said secondary winding
and said diode being also connected to a circuit which includes a series
connection of a resistor, a Zener diode and a diode, the diode conducting
from the grid of the switch MOS transistor towards the secondary winding,
while the Zener diode is connected in the opposite way round, the common
point of said secondary winding and of said series connection winding
being also connected to the anode of an other diode whose cathode is
connected to resistive mean, which opposite end is connected to the grid
of the power transistor, a capacitor being connected in parallel between
the cathode and the anode of said diode, the secondary winding being
connected by its end remote from said common end to the source of the
switch MOS transistor.
3. A circuit according to claim 1, wherein said first and second capacitor
means are selected in such a manner that the first means are not
sufficiently recharged to cause said switch to return to the
non-conductive condition in a half-period of the high frequency voltage.
4. A circuit according to claim 1, wherein the primary circuit is powered
by a DC voltage source and includes a switch which is made non-conducting
and conducting under the control of a modulated signal corresponding to
the high frequency voltage.
5. A circuit for controlling a DC/AC converter having four controlled
switches connected in an H-bridge configuration, wherein it is constituted
by a circuit according to claim 1.
6. A power supply circuit for a motor vehicle headlight discharge lamp,
said circuit including a DC/DC converter powered by the vehicle battery,
for example, a DC/AC converter powered by the DC/DC converter, and a
circuit for controlling the DC/AC converter, wherein the control circuit
is constituted by a circuit according to claim 1.
7. A motor vehicle headlight of the discharge lamp type, wherein the
discharge lamp(s) is/are powered by a power supply circuit according to
claim 6.
Description
The present invention relates to a circuit for controlling a DC/AC
converter in a power supply circuit for a discharge lamp of a motor
vehicle headlight.
BACKGROUND OF THE INVENTION
Proposals have recently been made to feed motor vehicle discharge lamps
with squarewave alternating currents at a frequency of about 200 Hz to 1
kHz.
FIG. 1 shows a circuit for providing that type of power supply.
The circuit comprises a DC/DC converter 1 powered with DC from the vehicle
battery B and a DC/AC converter 2 connected between the converter 1 and
the headlight discharge lamp 3. A high voltage pulse generator module 4 is
connected in series therewith for triggering the lamp 3.
The DC/AC converter 2 comprises four fast switches Q.sub.1 to Q.sub.4
connected as an H-bridge and controlled by a control circuit 6. The
switches Q.sub.1 to Q.sub.4 are MOS type transistors, for example, and the
control circuit 6 controls the grid voltages thereof. They must be capable
of withstanding isolated voltages in the range 0 V to 500 V in the
discharge lamp, and also currents in the range 0 A to 3 A, including
transients that may be as great at 10 A, lasting for a few hundredths of
microseconds.
These constraints require the various components of the circuit 6
controlling the switches Q.sub.1 to Q.sub.4 to be large in size. This
applies in particular to transformers included in such control circuits,
which transformers are dimensioned so as to be capable of withstanding
voltages of 500 V.
Unfortunately, it is presently desired that power supply control circuits
for discharge lamps should be considerably reduced in bulk so that such
circuits can be housed completely within headlights, whereas in the past
the converters of power supply circuits have been external to headlights.
OBJECTS AND SUMMARY OF THE INVENTION
An object of the invention is therefore to provide a control circuit of a
structure that enables its various components to be considerably smaller.
The structure of the invention also enables switching from one state to
another to take place in a very short period of time (less than about 1
ns), even though the H-bridge switches at low frequency (200 Hz).
To this end, the invention provides a circuit for controlling a DC/AC
converter of a power supply circuit for a motor vehicle headlight
discharge lamp, the circuit comprising a primary circuit, voltage-feed
means for feeding the primary circuit with voltage, and a secondary
circuit coupled to the primary circuit by mutual induction, the secondary
circuit delivering a voltage controlling the non-conductive and conductive
state of a MOSFET type transistor of the DC/AC converter, the voltage that
the power supply means deliver to the primary circuit constituting a
modulated high frequency carrier voltage, the secondary circuit including
means for converting the high frequency voltage delivered to the primary
circuit into a control voltage for the transistor that is greater than or
less than a given non-conductive or conductive threshold, as a function of
the modulation of said high frequency voltage, the conversion means of the
secondary circuit including a switch connected between the grid and the
source of the transistor, said switch being open circuit while a high
frequency voltage is being delivered to the primary circuit and short
circuiting the grid and the source of said transistor when the said high
frequency voltage disappears, said conversion means also including first
capacitor means providing the control voltage to the switch, and second
capacitor means which charge whenever the high frequency is being
delivered to the primary circuit and which discharge into said first
capacitor means when said high frequency voltage disappears, whereby said
first capacitor means then keep said switch in the conductive condition.
The term "high frequency" voltage is used in the present text to mean
frequencies of about or greater than 3000 kHz, with preferred frequencies
being about 2 MHz.
As will have been understood, the fact of using high frequency voltages
makes it possible to reduce to a very large extent the bulk of the
transformers in control circuits of the invention.
Advantageously, the control circuit of the invention includes the following
additional characteristics on their own or in any technically feasible
combination:
said first and second capacitor means are selected in such a manner that
the first means are not sufficiently recharged to cause said switch to
return to the non-conductive condition in a half-period of the high
frequency voltage;
the primary circuit is powered by a DC voltage source and includes a switch
which is made non-conducting and conducting under the control of a
modulated signal corresponding to the high frequency voltage; and
the circuit is a circuit for controlling a DC/AC converter that includes
four controlled switches connected in an H-bridge.
The invention also provides a power supply circuit for a motor vehicle
headlight discharge lamp, said circuit including a DC/DC converter powered
by the vehicle battery, for example, a DC/AC converter powered by the
DC/DC converter, and a circuit for controlling the DC/AC converter,
wherein the control circuit is constituted by a circuit of the
above-specified type.
The invention also provides a motor vehicle headlight of the discharge lamp
type, wherein its discharge lamp(s) is/are powered by a power supply
circuit of the above-specified type.
BRIEF DESCRIPTION OF THE DRAWINGS
Other characteristics and advantages of the invention appear further from
the following description. The description is purely by way of
non-limiting illustration. It should be read with reference to the
accompanying drawings, in which:
FIG. 1, as described above, is a diagram of a power supply circuit for a
discharge lamp in a motor vehicle headlight;
FIG. 2 is a block diagram showing how a circuit of the invention operates;
FIGS. 3a to 3c are diagrams of waveforms used in the circuit of FIG. 2;
FIG. 4 is a circuit diagram corresponding to a portion of a circuit
constituting one possible embodiment of the invention; and
FIG. 5 is a full circuit diagram of a circuit of the invention.
MORE DETAILED DESCRIPTION
The control circuit 6 shown in FIG. 2 comprises a logic unit 7 which
generates squarewave binary signals S.sub.fonc, of the type shown in FIG.
3a. Depending on the sense in which the H-bridge 3 is to operate, such a
signal S.sub.fonc has one level or another level.
The sense-control signals S.sub.fonc are applied together with a high
frequency carrier S.sub.P that is also generated by the logic unit 7 to an
input of a modulator unit 8. As shown in FIGS. 3b and 3c, two signals
S.sub.sens1 and S.sub.sens2 output by said unit 8 correspond respectively
to the carrier S.sub.P modulated by the sense-control signal S.sub.fonc of
FIG. 3a, and to the carrier S.sub.P modulated by the complement of the
signal of FIG. 3a.
These signals S.sub.sens1 and S.sub.sens2 control respective pairs of
switches, which are required to be opened or closed together. The signal
S.sub.sen1 controls the switches Q.sub.1 and Q.sub.2 while the signal
S.sub.sens2 controls the switches Q.sub.3 and Q.sub.4.
To this end, the signal S.sub.sens1 is applied to the primary windings of
two transformers T.sub.1 and T.sub.2, while the signal S.sub.sens2 is
applied to the primary windings of two other transformers T.sub.3 and
T.sub.4 (FIG. 2).
The secondary windings of the transformers T.sub.1 to T.sub.4 feed the
grid-source voltages of the transistors Q.sub.1 to Q.sub.4, each via a
respective circuit M.sub.1 to M.sub.4 that performs the following
functions:
the received high frequency control signal is filtered and the voltage
V.sub.gs between the grid and the source of the transistor is held above a
conductive state voltage +V so long as the high frequency sense-control
signal is present (functions symbolized by the unit F in FIG. 2);
the grid-source voltage V.sub.gs of said transistor is switched off quickly
whenever said signal disappears, with the transistor then being in the
non-conductive state (function symbolized by unit C); and
the corresponding transistor Q.sub.1 to Q.sub.4 is protected against
saturation of the transformers T.sub.1 to T.sub.4 (function symbolized by
the unit P).
One possible circuit for controlling a switch Q by means of one of the
signals S.sub.sens1 and S.sub.sens2 is shown in FIG. 4. The intermediate
transformer is given reference T therein.
The primary winding of said transformer T is connected:
at one end to a source of positive voltage +V.sub.cc (+12 volts); and
the other end thereof is connected to neutral or ground via a fast switch
Q.sub.11 controlled by one of the high frequency signals S.sub.sens1 and
S.sub.sens2 output from the modulator unit 8.
By way of example, the switch Q.sub.11 may be an MOS transistor having its
grid receiving said high frequency signal S.sub.sens1 or S.sub.sens2.
The secondary winding of the transformer T is connected at one end to the
anode of a diode D.sub.1 whose cathode is connected to a resistor R.sub.1.
The opposite end of the resistor R.sub.1 is connected to the grid of
transistor Q. A capacitor C.sub.3 is connected in parallel between the
cathode and the anode of the diode D.sub.1.
The other end of the secondary winding of the transformer T is connected to
the source of a MOS type transistor Q.sub.12. The grid of the transistor
Q.sub.12 is connected to a neutral point N.sub.1 between the secondary
winding and the diode D.sub.1 by means of a circuit that includes a series
connection of a resistor R.sub.3, a zener diode Z.sub.3 and a diode
D.sub.3. The diode D.sub.3 conducts from the grid of the transistor
Q.sub.12 towards the secondary winding, while the zener diode Z.sub.3 is
connected the opposite way round.
The grid of the transistor Q.sub.12 is also connected to a resistor
R.sub.2, whose end remote from the transistor Q.sub.12 is connected to the
cathode of a diode D.sub.2 whose anode is connected to above-mentioned
point N.sub.1.
A capacitor C.sub.1 is connected firstly to a point N.sub.2 between the
diode D.sub.2 and the resistor R.sub.2, and secondly to the source of the
transistor Q.sub.12.
A capacitor C.sub.2 is connected between the grid and the source of the
transistor Q.sub.12.
As will have been understood, the transformer T is connected in a "flyback"
circuit: i.e. it charges while switch Q.sub.11 is open.
So long as the high frequency signal is present, operation is as follows.
While the switch Q.sub.11 is closed, energy from the primary winding of the
transformer T is transferred to the secondary winding so the grid of
transistor Q charges via the diode D.sub.1 and the resistor R.sub.1.
The components R.sub.3, Z.sub.3, and D.sub.3 then maintain a negative
voltage across the terminals of capacitor C.sub.2 and on the grid of
transistor Q.sub.12.
Capacitor C.sub.1 charges to an initial value.
When Q.sub.11 opens again, capacitor C.sub.1 tends to recharge the
capacitor C.sub.2 via resistor R.sub.2.
C.sub.1, R.sub.2, and C.sub.2 are selected in such a manner that the
voltage across the terminals of C.sub.2 is prevented from rising to a
positive value that is great enough for causing C.sub.12 to conduct within
one-half period of the high frequency signal.
The grid of transistor Q therefore remains charged so long as the high
frequency carrier is present.
When the high frequency signal disappears, then capacitor C.sub.2 charges
to the same voltage as capacitor C.sub.1.
Transistor Q.sub.12 conducts, short circuiting the grid of transistor Q,
and thereby holding it in the non-conductive state until the high
frequency carrier reappears.
FIG. 5 shows the detail of a control circuit that includes circuits of the
type shown in FIG. 4.
The modulator unit 8 therein comprises four NAND type logic gates
referenced PL.sub.1 to PL.sub.4.
On respective first inputs, logic gates PL.sub.1 and PL.sub.2 both receive
the signal SP corresponding to the carrier at high frequency (e.g. at 2
MHg). The second input of gate PL.sub.1 receives the sense-control signal
S.sub.fonc of FIG. 3a, while the gate PL.sub.2 receives the complement
thereof.
The output signals from the gates PL.sub.1 and PL.sub.2 are applied as
input signals respectively to the gates PL.sub.3 and PL.sub.4 which also
receive a control voltage V.sub.cc1.
The output signals from the gates PL.sub.3 and PL.sub.4 correspond to the
signals S.sub.sens1 and S.sub.sens2 of FIGS. 3b and 3c.
The various logic gates PL.sub.1 to PL.sub.4 may be of the IC7 74 HC00D
type.
The outputs from the gates PL.sub.3 and PL.sub.4 are applied to filter
circuits each comprising a 47 ohm resistor R.sub.10 in series with a 3.30
Henry inductor L.sub.1 together with a parallel-connected capacitor
C.sub.11 having a capacitance of 100 picofarads between neutral and the
output point of the circuit.
The outputs from these filter circuits are applied to the grids of two MMT
960 type MOS transistors that correspond to the transistor Q.sub.11 in
FIG. 4.
The sources of these two transistors Q.sub.11 are connected to neutral. The
drain of each of these two transistors Q.sub.11 is connected to two
primary windings of two transformers T via 120 ohm resistors R.sub.11. 200
picofarad capacitors C.sub.12 are connected in parallel between the drains
of said transistors Q.sub.11 and neutral.
At their opposite ends, the primary windings of the four transformers T are
connected via a common node firstly to a voltage source +V via three
parallel-connected resistors R.sub.12 each having a resistance of 33 ohms,
and secondly to a capacitor C.sub.13 having a capacitance of 0.47
microfarads and having its opposite connected to neutral.
The four transformers T are of the 23Z100SM type and they are compact.
The secondary windings of these various transformers T power, respectively,
the four grid-source voltages of the four transistor Q.sub.1 to Q.sub.4
(not shown in FIG. 5) via four secondary circuits of the type shown in
FIG. 4.
The resistance of R.sub.3 is 220 ohms.
The zener diode Z.sub.3 is of the BZXB4C4D3 type.
The diode D.sub.3 is of the BAS16 type.
The capacitor C.sub.2 has a capacitance of 220 picofarads.
The resistor R.sub.2 has a resistance of 22 kohms.
The capacitor C.sub.1 has a capacitance of 0.1 microfarads.
The resistance of R.sub.1 is 47 ohms.
The capacitance of capacitor C.sub.3 is 100 picofarads.
The control circuit described above by way of example is sufficiently
compact to be contained in a housing having a volume of 16 cm.sup.3.
Naturally, other variants of the invention are possible. In particular
voltage +V or V.sub.cc may be provided by the DC/DC converter in order to
overcome variations in battery voltage.
Top